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Home My WebLink AboutSubsoils Report for Foundation DesignHuddleston-Berry 2789 Riverside Parkway Grand Junction, Colorado 81501 Phone: 970-255-8005 Info@huddlestonberry. comEngineering &'Festing, LLC hne 6,2023 Project#02648-0001 Tom and Naomi Laidlaw 234 Cowtty Road 236 Silt, Colorado 81652 Subject:Geotechnical Investigation Parcel 218105300294 Silt, Colorado Dear Mr. and Mrs. Laidlaw, This letter presents the results of a geotechnical investigation conducted by Huddleston-Berry Engineering & Testing, LLC (HBET) at Parcel 218105300294 in Silt, Colorado. The site location is shown on Figure t. The proposed construction is anticipated to consist of a new single-family residence. The scope of our investigation included evaluating the subsurface conditions at the site to aid in developing foundation recommendations for the proposed construction and to evaluate the site soils for an Onsite Wastewater Treatment System (OWTS). Site Conditions At the time of the investigation, the site was open and generally sloping down to the soulh. Vegetation consisted primarily of pasture grasses, weeds, and trees in the center portion of the site. The site was bordered to the north by I-70 Frontage Road, to the west and east by rural residential/agricultural properties, and to the south by the Colorado River. Subsurface Investieation The subsurface investigation included five test pits as shown on Figure 2 - Site Plan. The test pits were excavated to depths of 5.0 and 8.0 feet below the existing ground surface. Typed test pit logs are included in Appendix A. As indicated on the logs, the subsUrfacb conditions encountere d at thesite were slightly variable. Test Pits TP-l, TP-z, TP-3, and TP-5 encountered 1.0 foot of topsoil above, brown, moist, medium stiff lean clay soils to the bottoms of the excavations. Groundwater was not encountered in TP1, TP'-2,TP-3, or TP-5 at the time of the investigation. Test Pit TP-4 encountered 1.0 foot of topsoil above tan to brown, moist, dense well-graded sand with silt, gravel, cobble, and boulder soils to the bottom of the excavation. Groundwater was not encountered in TP-4 at the time of the investigation $ a a .\ .\ N Parce1218105300294 ,A#02648-000r offBi))F"#,,.._T?l*3fl o6to6t23 \sry Laboratorv Testins Laboratory testing was conducted on samples of the native soils encountered in the test pits. The testing included grain size analysis, Atterberg limits determination, natural moisture content and density determination, swell/consolidation testing, and maximum dry density and optimum moisture content (Proctor) determination. The laboratory testing results are included in Appetrdtx B. The laboratory testing results indicated that the native clay soils are moderately plastic. In addition, the native clay soils were shown to tend to consolidate under loading at their existing density. However, based upon the Atterberg limits of the material, the native clay soils are anticipated to be slightly expansive when compacted and introduced to excess moisture. The native sand soils were indicated to be non-plastic. In general, based upon the density of the material and upon the presence of large particles, the native sand soils are anticipated to be fairly stable under loading. Foundation Recommendations Based upon the results of the subsurface investigation and nature of the proposed construction, shallow foundations are recommended. Spread footings and monolithic (turndown) structural slabs are both appropriate foundation alternatives. However, in order to provide a stable bearing stratum and limit the potential for excessive differential movements, lt is recommended ft foundations be constructed above a minimum of 24-inches of structural fiIl. Due to their plasticity, the native clay soils are not suitable for reuse as structural fill. However, t7^^ --r)--^ -^--1 ^^:1- ^---l---i-.^ ^x t^,^-^)1 ^--^ ---ir^1-1^ f^-- --^--^^ -1 Cl1. ^-^--:)^lur(' llilLtvE salllu liulls, ti.llutusrvE ur tupsurrr alrtt sullaulE rul lttustt a5 suuuturitrl illr, PruvruEu particles in excess of 3-inches in diameter are removed. Imported structural fill should consist of a granular, non- expan siv e, Ig!fugJrul4lry.material approved by HBET. For spread footing foundations, the footing areas may be trenched. However, for monolithic slab foundations, the structural fill should extend across the entire building pad area to a depth of 24- inches below the furndown edges. Structural fiIl should extend laterally beyond the edges of the foundation a distance equal to the thickness of structural fill. Prior to placement of structural fill, it is recommended that the bottom of the foundation excavation be scarified to a depth of 6 to 9 inches, moisture conditioned, and compacted to a minimum of 95% of the standard Proctor maximum dry density, within * 2% of the optimum moisture content as determined in accordancc with ASTM D698. Structural fill should be moisture conditioned, placed in maximum 8-inch loose lifts, and compacted to a minimum of 95% of the standard Proctor maximum dry density for fine grained soils and 90% of the modified Proctor maximum dry density for coarse grained soils, within * 2Yo of the optimum moisture content as determined in accordance with ASTM D698 and D1557, respectively. @endedtowithin0'1-feetofthebottomofthefoundation.Nomore than O.l-feet of gravel should be placed below the footings or hrrndown edge as a leveling course. 2Z;V008 ALL PROJECTS\02648 - Torn and Naorni Laidlaw\02648-0001 Parcel 21 8 1 05300294\200 - Geo\02648-0001 LR060623.doc Parcel 218105300294 #02648-0001 06/06/23 Huddleston-Beray en$rerdn{ & t6rint' t"LC For structural fill consisting of the native sand soils or imported granular materials, and foundation building pad preparation as recommended, a maximum allowable bearing capacity of 1,500 psf may be used. In addition, a modulus of subgrade reaction of 150 pci may be used for ffigofthenativesandsoilsandamodu1usof200pcimaybeusedfor suitable imported structural fill. Foundations subject to frost should be at least 36 inches below the finished grade. Aqy stcqwallq or retaining walb $ho-uld be dEsrgqed ta resist laleral earta pressures, Fqr baqklll consisting of the native soils or imported granular, non-free draining, non-expansive material, we recommend that the walls be designed for an active equivalent fluid unit weight of 50 pcf in areas where no surcharge loads are present. An at-rest equivalent fluid unit weight of 70 pcf is recommended for braced walls. Lateral earth pressures should be increased as necessary to reflect any surcharge loading behind the walls. Water sqhrbte sulfates are eemluan to the sorls in Wssterq eoloradq, Therefore, at a sdttutuu, Type I-II sulfate resistant cement is recommended for construction at this site. Non-structural Floor Slab and Exterior Flatwork Recommendations In order to reduce the potential for excessive differential movements, it is recommended that non-structural floating floor slabs be constructed above a minimum of 24-inches of structural fill with subgrade preparation, structural fill materials, and fill placement be in accordance with the Fewdqtien ReQemmendatiqryg SEqtion of this report, It ig recommEnded that Exteriqr flatwork be constructed above a minimum of l2-inches of structural fiIl. Drainase Recommendations Gradins and drainaee are critical for the lons-term oerformsnce of the structure and grading around the structure should be designed to carry precipitation and runoff away from the structure. It is recommended that the finished ground surface drop at least twelve inches within the firSt terr feEt 4rvay frgm thq Structrlrq, It iS alsq recommended that landgcaping within five feet of the structure include primarily desert plants with low water requirements. In addition, it is recommended that irrigation, including drip lines, within ten feet of foundations be minimized. HBET recommends that downspout extensions be used which discharge a minimum of 15 feet from the structure or beyond the backfill zone, whichever is greater. However, if subsurface downspout drains are utilized, they should be carefully constructed of solid-wall PVC and should daylight a minimum qf 15 feqt frqm thp strygturq, In addition, al impermeable membrane iS recommended below subsurface downspout drain lines. Dry wells should not be used. Onsite Wastewater Treatment Svstem Feasibilitv In order to evaluate the site soils for onsite wastewater treatment, percolation testing was conducted at the site in accordance with Garfield County regulations, The percolation rate in the native soils was determined to be approximately 40 minutes-per-inch. The percolation testing data are included in Appendix C. ln accordance with Garfield County regulations, a percolation rate of between 5 to 60 minutes- per-inch is required for soils to be deemed suitable for onsite wastewater treatment. Therefore, based upon the results of the percolation testing, HBET believes that the native soils are suitable for onsite wastewater treatment. JZ:V008 ALL PROJECTS\02648 - Tom and Naomi Laidlaw\02648-000 I Parcel 2 I 8 I 05300294V00 - Geo\02648-0001 LR060623.doc Parcel 218105300294 #02648-000i 06t06123 ln addition to the percolation rate of the subsurface materials, the seasonal high groundwater elevation is an important factor in determining the suitability of the site for Onsite Wastewater Treatment Systemi. For OWTS suitability, the seasonal high groundwater elevation should be at least four fiet below the bottom of the- proposed absorption bed. As discussed previously, grouldwater was not cncountered at ttre iime ot'the investigation. However, based upon the firoximity of tho site to thc Coloradu River, the seasnnal high groundwator slevation likely matches the seasonal high water level in the river. In accordance with Garfield County regulations, the bottom oi th" Soil Treatment Area (STA) will need to be at or above the 100 year flood elevation (determined by others). General Notes The recommendations included above are based upon the results of the subsurface investigation and on our local experience. These conclusious aud recommendations arc volid only for the proposed construction. As discussed previously, the subsurface conditions encountered at the site were slightly variable- However, the precise nature and extent of any subsurface variability may not become evident u'til construction. As a result, it is recommLnded that HBET provide construction materials testing and engineering oversight dwing the entire construction process. ln addition, the builder and airy subcJntracto[ workiirg ott thi prnject should bc provided a copy. of this report and informed of the issues associated with thl pi"s"ttc" of moisture sensitive subgrade materials at this site. It is important to note that the recommendations herein are intehdgd to -refuce the risk Qf d",sr"us. astociot"d *it!, vol4t*e qhanee q.f ihe i lone-te_,rm chaneqs in subsurfqce moiFlare efieq or vofume chgnse.. Where significant ce moisture occqr due to onor nradifg_, imltoner stormwalet r gthe'"aose.' eith"' durioe constry"tio! eryt= incnes p,f movemelt are ogssibl:' Ip ndgtions in lhis le-ort releases Huddleston- liabilitv with reeard to thg sWcture " "ormance. We are pleased to be of service to your project. Please contact us if you have any questions or comments regarding the contents of this report. Respectfully Submitted: Iluddleston-Berry Engineering and Testing' LLC Michael A. Berry, P.E' , ' Vice President of Engineering @*m***;P-r,H 4 Z:V008 ALLpROJECTS\02648 - Torn andNaomi Laidlaw\02648-0001 Parcel 218105300294900'Geo\02648-0001 LR060623'doe FIGURES GlqPghlic,Het* Garfielci County, CO Location D ate cr e ated: 4 / 21J 2023 Last Data Uploadedl. 4/21/2O23 2:07:23 AM FIGURE 1 Site Location Map Deverooed bv{;:} Fg$fg'df l 6qPuhlic,llGt'' Garfield County, CO FIGURE 2 Site PlanD ate cr e atedt 4 / 2!/2Q23 Last Data Uploaded:4/2!/2023 2:07:23 AM D eve roned bv1$) Fsltg}"^drt APPENDIX A Typcd Tcst Pit Logs GEOTECH BH COLUMNS (}2648-000I GINT !v em C)-{zc, =trmn oN6)s @ooo otrmz{ -lo 3 0t c-z!)o 3. r- 0) il € s n |-J ra! -1ff-tFoD 6= '5e:Eq=!-a*e r! 9 =l+vt 7(;o aw50(D oFqo+rrl -<tF;E F' 5.5 oc ts -to 3.B sc F.) !vg m C){ oo 6z !vg mo{z =m ! 0t og. N @ o('r (r)ooN(o5 q. bo {ma{ !{zc =-EIrnitn*{ qP AI zo{m(D 5oomo E -{o mxo 6z 3m{Io E' nxo -t6zooz{n o-{ov Eo(D d o- E, -{na{ v-{mo A N5 N Cr) oIlltoxm E, @ qt -tilox =ID 0to-Joo oo3! m-{m0 Imv mxct I6z { mz E'o.l'| mxo -{6z -{ _{ =mo.l| mxo 6z ovo zo = ma m m 6 5 N5 Nq, ouoczc' m tn 6z o e g ? {ma !{ aNlll Po DEPI-H (ft) GRAPHIC LOG +mvtr Um(tov-(, -loz SAMPLETYPE NUMBER RECOVERY % (RAD) BLOW COUNTS (N VALUE) POCKET PEN. (tsf) DRY UNITWT (pcO MOISTURE CoNTENT (%) -{r- -l =x-{ tD6mvo FINES CONTENT %l LIQUID LIMIT PLASTIC LIMIT PLASTICITY INDEX i:-.'f-: r:.' l'J 1,-. .r.f .'y4.'.r*l r\ . t/,. ,\ . .t/ aqt 5 o ot =.J o (a !) 6'(n --{o! @or r.o 0)5 or ov g 6€F 3oo5i 3osc 3 o =t @o o 3 o oo E 0' 90(> oo BH 2rEl0530o294.GPJ G|NT !v emo{z L =trmv oNo,5 @ooo or m2{ {of A)5oz 0)o 3.rg. e 0)€ \or-tJ+ _{ff_=r=r -'-:J \o*q-lrJ6' i"E 6 6'9ga ?(jo dg50Cf" -:,O p"( O ;l lrl @S0e;E F' oc R..to Egq t-r{.) !v emo-l 5o 9 ler lo lo I I I I I I I I I !vog m C){z =m -It o) oo lru lo LoI(r (J)oo LN(oA {ma{T {zc =-ETM H,i I -{qP -.N zo-{mv, ooo m tr, E rnxf) D 6z =m{ o tr, -{o CJF @octli oo mxc' 6zooz-{v c)-tov =c G trv c, -{mo{ v{nc' 5 l\)s No) {o () Illlclxmo ID @ oo =!rm-'lm E, A N)A N)a) TmF mxo Ioz { mztroal mxo -{6z g a 6lvo>,-ro #E9s HHshJoz o ? ovoCzc, m m -{6z .{ ma{ c{ 92Nm DEPTH (ft) GRAPHIC LOG +mn rom @ov !Ioz. SAMPLE TYPE NUMBER P.ECOVERY % (ROD) BLOW COUNTS (N VALUE) FOCKET PEN. (ts0 DRY UNIT WT (pef) MOISTURE CoNTENT (%) { --1=msv -{ TD(Dmvo FINES CONTENT (%) LIQUID LIMIT PLASTIC LIMIT PLASTICITY INDEX ('r l-l"' l* I t- .l._..t,_ . t-: .-4. t\r-'ty- . t=. .1-: - i,-. .ls . ',;;.'. ls; r\, .f/e . {! . t.-, t\ .t.} root or ov(t d€ .J 3 9.of 3osc 3 @4 a, 0,5o- a 0t €. 5 o (o 0)5oo --lo-o U,o f- @o o 3 o (Do -)+ Ot Ito oo BH 81 TAB.GDT 6/5123 Tv emc'{zc =Emv oI\)o,56ooo otrmz{ {o 3 !)t CLz 0)o 3. t- o,a o € €^Nti -tff{=oD mx.r-!J s= 6=#flcic5.n Oe9A?;6'A w300 O p'( O+rr1 6<tic;E E'oi; 5 oc R" .Jo ts' sq trto !7 em(){ 5o 6z I 'o o !v P mc)-{z =m -It q) oo l\) @ o('' (l'oo N)(o5 {m U,{rg {zC =TEm7{!I(.) '(, om o'n zo{ u I I ooomc, TD -to mxo 6 = =m-{+oc' -l!)c)7i =TD otox5o(D mx C) {6zooz-{2 o{ov g tilt atI v{mc' $ Ns N Ct) o+ nroxmot! @ =oo 0) o c)o =! m{ INTI + N5 Ngt ovo z E m m { 6z 'll-lm2 mxo 6z { mzcto'n mxo -{6z o e ovo>,-lo #Eqs ilHFh 62 o Q {m(t -.1! LNI'l o DEPTH (ft) GMPHIC LOG +mvtr(, mac)7-t{oz. SAMPLE TYPE NUMBER RECOVERY % (ROD) BLOW COUNTS (N VALUE) POCKET PEN. (tsf) DRY UNITWT. (pcr) MOISTURE CoNTENT (%) {r{=msV -{Eamv 6) FINES CONTENT &l LIQUID LIMIT PLASTIC LIMIT PLASTICITY INDEX ": :t\-.. j+'.r:'.'r-'. r:..'1., i*. : l.-.'.1\: .' tt .r.l . 1..-.'. .r*: .1- L\- t.>-1\ tt,. t\..tt, v) 0)5o- o 0t E. odD5- c)v,{o-ttaIt- Or l^ l- I l^,I I t-o 0) c)r ovo a€ -: 3so-3ogc 3tt*, t!o o 3 o o an E 0! lrt (Do :-+ GEOTECTI BH COLUI{NS 026.18.000I PARCEL 218IO53OO294.GPJ GINT US LAB.GDT 6/'23 !v e mo-{v 3trlllv oN O)5(D ooo o mz{ -{o3 0) az 0)o :. t- 9-g 0l € \O r- N.) !a'!{ff{Fos mt.r-5€* u:-td6' d"E X 69ga ?rlo aw50(l c);"<o+E'r 6<oa GE F'oi; crc Fe -.1o 9. sqt.l.(^) !a Pno-l 5ot6z a -o o !vg mo+z =m .It !)5og N @ o<t(r'oot9(os {mo{ ! -{zc =trmv {T T5 1' o lill o-n zo-tmo ooomo E mxo 6z 3m-{Io E mxo {6z c)ozIu o-{ov € ]T (Eg e tr, mo It-{mo 5 N5 N AJ -lo -l Eo ^.5 E Dor:toD o+moxmtr @ TD oo3! m-lmtr' s NA N) C'J Imf, mxo 6z mztr' o'n mx() -{6z o? o,o>=-ro #Eqi: HEsh oz If,? ovILz E m m 6z {mo-{3 LNm o DEPTH (ft) GRAPHIC LOG {mv roma,ovt-{oz SAMPLE TYPE NUMBER RECOVERY % (ROD) BLOW COUNTS (N VALUE) POCKET PEN (tsO DRY UNITWT (pcO MOISTURE CoNTENT (%) -lr-l =msio it!6mno FINES CONTENT (%t LIOUID LIMIT PTASTIC LIMIT PLASTICITY INDEX N I ffii,ii.Jii=,r'Pr,ti o @ ::rqt d oA' or.o, @g: 6e =q.aG) >sYO -oqto =* (to>erZds€5 3aO=(,r-tr 6) 8E;6(D*g, ooctq oI 0, o @ozooa o ot =.e @o o3 o o ah E. o 5rrO o(D- {o1'aor 3) (3 oI! O) z.It z-u zl, o l-l^ !v P mc){zc =trmv otrmz{ -lc 3 !t5 3-zl) !. T 9.g 0t E \onfJn!{ff{Fop 6=-r- 5 sF Sz ).fr.&5 d o9ga ?uo dw.poE O.'(o+81 rcl{rc;E F-oX 5. 0a R" -lo sq r<r{o .ovoL mc){ 5() _Ioz !voe mo-{z =m ! o)-o P- N E o('l(,) oN(or {lrl U,{ ! -{zc =-E>mii'*{ 9P - g,r zo -lm CD 5oomo ID -{c) mxo 6z3m-{ o E mxc' 2 -{6z ooz{n o-{ov E, FIo-{ v{Itto 5 N5 N G)-tiloFJ ID!)o- ooo :Enoxm tr, ID =oo o o-c)o =Er lln-{nrq' ls INl5 ovoEz E' mrm 62 I I I I {mu,{!-t !2Nm ovo+rr= *E#ExHqs sgHH r96 g ?o a c 3 DEPTH (ft) GRAPHIC LOG +mn rg m @ov.It Ioz SAMPLE TYPE NUMBER RECOVERY % (RaD) BLOW COUNTS (N VALUE) POCKETPEN. (tsO DRY UNITWT (pcf) MOISTURE coNTENr e/o) -{r{ =m=V{IDgrmvo FINES CONTENT %l LIQUID LIMIT PLASTIC LIMIT PLASTICIry INDEX l\' in .r-r ..r-. .:.- l-,'tt.r.i f-:.'.r*: r\ . tr_. ,\ . .tzl C"o =o. o ot €. o (cI It)5. c)o Jot, @or o ID j l-ooo otoo o CL t-oq) ot- c)r:- cr o€: 3g cnj+ 3oo.c 3 o x o (o (C' NN (s -otD { o)A @ ('r @$ t!orto3 o oo E o) 9D<) (Do APPEI\DIX B Laboratory Testing Results N D @ Huddleston-Berry Engineering & Testing, LLC 2789 Riverside Parkway Grand Junction, CO 81501 970-255-8005 GRAIN SIZE DISTRIBUTION CLIENT Tom and Naomi Laidlaw PROJECT MME Parcel 218105300294 PROJECT NUMBER 02648-0001 PROJECT LOCATION SiIt. CO U.S. SIEVE IN INCHE$ I U.S. SIEVENUMBER$HYDROMETER3461420 30 40 FIo [! B CD & tJjz LL Fz LrJot[! o- 100 95 90 85 80 75 70 65 60 55 50 45 40 35 30 25 20 15 10 5 0 10 1 GRAIN SIZE IN MILLIMETERS 0.1 0.01 0.001 COBBLES GRAVEL SAND SILT OR CLAY coarse flne coarse medium fine nII't? \1 1 I ll \q \ I ) \ Specimen ldentifi cation Classification LL PL PI Cc Cu o TP4, GB-l 4t24 WELL-GRADED SAND with SILT and GRAVEL(SW-SM)NP NP NP 1.88 12.90 tr TP-s, GB.l 4t24 LEAN GLAYwith SAND(CL)u 1g 15 Speeimen ldentification D100 D60 D30 D10 %Gravel %Sand o/oSilt o/oClay o TP*4, GB-l 4124 37.5 0.964 0.368 26.9 63.1 10.0 tr TP-s, GB-1 4t24 2 0.0 15.9 u.1 Huddleston-Berry Engineering & Testing LLC 2789 Riverside Parkway Grand Junction, CO 81501 970-255-8005 AfiERBERG LIMITS' RESULTS CLIENT Tom and Naomi Laidlaw PRq'ECT NAME Parcel 218105300204 PROTECT NUT BER 02648-0001 PROJECT LOCATION SiIt, CO @ P L A S T I c I T I N D E X 50 40 30 20 10 CL.ML @ @ 40 100 LIQUID LIMIT Specimen ldentification LL PL PI #200 Ctassification o TP,4, GB-l 4t24 NP NP NP 10 VlrEtt-cRADED SAND with SILT and GRA\/EL(SW€M) E TP.s, GB-t 4124 u 19 15 84 LEAN GLAYwith SAND(GL) Foq 6 5 v,f Fz 6 Lo sNoooQ6 a N N D @ o5 Fzo N Jt!ot I z aEFaJoozo(.) Huddleston-Berry Engineering & Testing, LL,C 2789 Riverside Parkway Crrand Junction, CO 81501 970-255-8005 CONSOLIDATION TEST CLIENT Tom and Naomi Laidlaw PRo.TECT NAME Parcel 218105300294 PRO'ECT NUMBER 02648-0001 PRO'ECT LOCATION SiIt, CO 4.4 4.6 4.8 5.0 5.2 5.4 s 2 uF(t) 5.6 5.8 6.0 6.2 6.4 6.6 6.8 7.0 100 1,000 10 STRESS, psf Specimen ldentification Ta MC% ) \ \ \ \ \ \ \ \ \ ) \ \ \ \ \ \ \ () o TP-s, MC-l 2.O Classification 99 22 o6o "56 No zo F(-) o Eoo Huddleston-Berry Engineering & Testing, LLC 2789 Rivemide Parkway Grand Junction, CO 81501 970-255-8005 MOISTU RE.DENSITY RELATIONSH IP CUENT Tom and Naomi Laidlaw PR(NECT NAME Parcel 218105300294 PROJECT NUMBER 02648.0001 PROJECT LOCATION sitt. co Sample Date: Sample No.: Source of Material: Description of Material N2412023 145 TP.5-GB.1 LEAN GI.AY with SAND(CL) Test Method (manual):ASTM D698A 140 135 TEST RESULTS Maximum Dry Density 105.0 PCF Optimum Water Gontent 18.5 % 130 125 GRADATTON RESULTS (% PASSING) #200 #4 3t4" 84 100 100 ootF =z uJo to ATTFPRtrPI? I IMlT_q 1 20 LL PL PI 15u19 115 Curves of 100% Saturation for Specific Gravity Equalto: 110 2.80 2.70 2.60 105 100 95 90 5 15 WATER CONTENT, % 0 10 20 25 30 APPENDIX C Percolation Testing Results PERCOLATION TESTING STP322rluoctcston-bcrry fngincc(itrg & 'fc:{iiIgt t-l-C Project Name: Parce|218105300294 Location:sitt, co Testing Conducted By: T, Collins Suporvising Engineer; M, Berry TEST PIT DIMENSIONS SOIL PROFILE 02648-0001 1 Project No. Test Pit No. Date: Length (ff) widrh (fi) Depth (ft) Water Level Depth (ff) Oepth (ft)Not Enesuntered 8,0 X Depth {ft}Description Remarks 0-1 Sandv Clav with Orqanics (TOPSOIL) 1-8 Lean CLAY (cl), brown, moist, medium stiff Test Number: 1 Top of Hole Depth:--f (tt) Diameter of Hole: 3 (in) Lrepln or Frore; tY (tn) Tirne (min.) Wat6r Depth (in.) Change (in.) 0 1,5 10 2 0.5 20 2.25 0,25 30 3 0.75 40 3.25 0.25 50 3.5 0.25 60 3.75 0.25 70 4 0.25 80 4.25 0.25 90 4.5 0.25 100 4.75 0.25 1{0 0,2 ,1?A , 6,t5 0;?6 40Rate (minlin) Test Number'. 1 Top of Hole Depth:-f ttl Diameter of Hole: 3 (in) ueprn oT nore: 15 (tn) 40 Test Number: _ Top of Hole Depth: - (ft) Diameter of Hole: _(in) uepm or Frore: _(tn) Tinne {min,) Water Depth (in.) Change (in.) 0 1.875 10 2.375 0.5 20 2.875 0,5 30 3.125 0.25 40 3.375 0.25 50 3.625 0.25 60 4.125 0.5 70 4.625 0.5 80 5.125 0.5 90 5.375 0.25 100 5.625 0.25 110 5,875 0.25 120 6,125 0.25 40 Time (min.) Water Depth (in.) Change (in.) Average Percolation Rate (min/in): Rate (min/in)Rate (min/in): PERCOLATION TESTING sTP322Ifuddlestnn-Berry f4ugi$ccri{g & Tcsrirtg" Lf..(: Project Name: Parcel 218105300294 Location silt, co Testing Conducted By: Supervising Engineer: TEST PIT DIMENSIONS SOIL PROFILE Test Number: I Top of Hole Depth:Tttt) Diameter of Hole: Depth of Hole: 3 (in) 1s (in) Tirne (min.) Water Dep.th (in.) Change. (in.) 0 1.375 10 2.125 0.75 20 2.625 0.5 30 3.125 0.5 40 3.375 0.25 50 3.625 0.25 60 3.875 0.25 70 4.125 0.25 80 4.375 0.25 90 4.625 0.25 100 4,875 0.25 110 5.12,5 0.25 120 5.375 0.2s 40Rate (min/in) T. Collins M. Berry Test Number: _ Top of Hole Depth: - (ft) Diameter of Hole: _ (in) Depth of Hole: _ (in) Test Number; Top of Hole Depth: - (ft) Diameter of Hole: _ (in) Depth of Hole: _ (in) Length (fr) width (ft ) Depth (f0 Water Level Depth (ft) Depth ('ft),Not Eneountered 5.0 X Depth .tft)Description Remarks 0-1 Sandv Clav with Orqanics (TOPSOIL) 1-5 Lean CLAY (cl). brown, moist, medium stiff Tlme (min.) Water Depth tin.) Ghange {in.) Water Depth fin.) Change (in.) Time (min,) I Average Percolation Rate (min/in): Rate (min/in):Rate (min/in): PERCOLATION TESTING sTP-322ntll.l(ll€S[on-I'erry ]aiglncerirlg & Tcltitg, t,I-f"' Project Name: Parce|218105300294 Location:silt, co Testing Conducted By: T. Collins Supervising Engineer: M. Berry TEST PIT DIMENEIONE SOIL PROFILE TP-3Test Pit No. Date: Length (ft) widrh (fr) Depth (ft)Depth (ft)Not Encountered 5.0 X Depth (ft)Deseription Remarks 0-1 Sandy Clay with Organics (TOPSOIL) 1-5 Lean CLAY (cl), brown, moist, medium stiff Test Number: 1 Top of Hole Depth:--f (tt) Diameter of Hole: 3 (in) n^^+L ^J Lr^r^. -m /i.-\utrPr.il ur rruru. to UIl, Time (min,) Water Change (in.) 0 1.5 10 2 0,5 20 2.25 0.25 30 tq 0.25 40 2.75 0.25 50 3 0.25 60 3.25 0.25 70 3.5 0.25 80 3.75 0.25 90 4 0.25 100 4.25 4.25 1,1'0 fia 4.75 O.2:,5 40Rate (min/in): Test Number: 1 Top of Hote Depth:Ttnl Diameter of Hole: 9_ (in)_^uepur or nore: t6 (tn) Test Number: Top of Hole Depth: - (ft) Diameter of Hole; _ (in) Depih of Hoie: _ (in) 40 Time (min.) Water Dep.th (in.) Change {in.} 0 1.5 10 2 0.5 20 2.25 0.25 30 .E 0.25 40 2.75 0.25 50 3 0.25 60 3.25 0.25 70 3.5 0.25 80 3.75 0.25 90 4 0.25 100 4.25 0.25 1't0 0.25 120 4.75 0.25 40 Time (min,) Water Depth (in.) ehange Average Percolation Rate (min/in): Rate (min/in):Rate (minlin):